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\begin{aligned} & (\sigma_1,\sigma_2) \mapsto exp(-t d(\sigma_1,\sigma_2)) \;\; \text{is conditionally positive kernel} \\ \\ \overset{??}{\Leftrightarrow} \;\;\;\; & \frac{1}{n!} \sum_{\sigma \in Sym(n)} exp\big( t \cdot cycles(\sigma) \big) \;\le\; \left(1+\frac{1}{n!}\right) e^{t n} \end{aligned}

$\ldots$

Let $n \in \mathbb{N}$ , $n \geq 2$ . On the complex linear span $\mathbb{C}[Sym(n)]$ of the set of permutations on $n$ elements, consider the sesqui-linear form

(1)

\array{ \mathbb{C}[Sym(n)] \times \mathbb{C}[Sym(n)] & \overset{ \langle -,- \rangle }{\longrightarrow} & \mathbb{C} \\ ( a_1 \cdot \sigma_1 ,\; a_2 \cdot \sigma_2 ) &\mapsto& a_1 a_2^\ast \, 2^{ (\#\!cycles(\sigma_1 \circ \sigma_2^{-1})) } }

Question: Is (1) positive semi-definite?

Non-Answer: This here is not a counter-example:

Consider

$\sigma_3$ the cyclic shift by 1
$\sigma_1$ the cyclic shift by 2
$\sigma_2$ the cyclic shift by -2 (i.e. in the other direction)

Then if $n = 3 \cdot 4 \cdot k$ is divisible by 12, we have

$\#\!cycles (\sigma_1 \circ \sigma_3^{-1}) = \#\!cycles(\text{cyclic shift by 1}) = 1$
$\#\!cycles (\sigma_1 \circ \sigma_2^{-1}) = \#\!cycles(\text{cyclic shift by 4}) = 4$
$\#\!cycles (\sigma_2 \circ \sigma_3^{-1}) = \#\!cycles(\text{cyclic shift by 3}) = 3$

and hence

\begin{aligned} & \left\vert \sigma_1 - \sigma_2 + \sigma_3 \right\vert^2 \\ & = \left\vert \sigma_1 \right\vert^2 + \left\vert \sigma_2 \right\vert^2 + \left\vert \sigma_3 \right\vert^2 - 2 \langle \sigma_1, \sigma_2\rangle - 2 \langle \sigma_2, \sigma_3\rangle + 2 \langle \sigma_1, \sigma_3\rangle \\ & = 3 \cdot 2^n -2 \cdot 2^{4} - 2 \cdot 2^{3} + 2 \cdot 2^1 \end{aligned}

Last revised on February 10, 2020 at 05:49:54. See the history of this page for a list of all contributions to it.

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